Flowline, Inc. | 10500 Humbolt Street, Los Alamitos, CA 90720 p 562.598.3015 f 562.431.8507 w flowline.com MN301520 Rev A1

LC40, LC41 and LC42 Series Manual

Switch-Pro™ Remote Level Controller

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Introduction / Table of Contents Step One

The LC40, LC41 & LC42 Series Controllers are general-purpose level controllers offered in three configurations for pump and valve control. The LC40 Series features a single 10A SPDT relay output and can accept one level sensor as an input. The LC41 Series features a single 10A SPDT latching relay output and can accept one or two level sensor(s) as an input. This package is ideal for the automatic filling or emptying of a tank. The LC42 Series features both a single 10A SPDT and a single 10A Latching SPDT relay. This package allows for a three-input system that can perform a automatic operations (fill or empty) and an alarm operation (high or low). The LC42 series can also be a two-input controller that can perform dual alarms (2-high, 2-low or 1-high, 1-low). Package either controller series with level switch sensors and fittings. FEATURES

Fail-Safe relay control of pumps, valves or alarms with a 0.15 to 60 second delay Polypropylene enclosure can be DIN rail mounted or back panel mounted. Easy setup with LED indicators for sensor(s), power and relay status. Invert switch changes relay state from NO to NC without rewiring. AC powered

TABLE OF CONTENTS Specifications / Dimensions: ................................................................................................................................. 3 Specifications: ........................................................................................................................................... 3 Dimensions: .............................................................................................................................................. 3 Safety Precautions: ............................................................................................................................................... 5

Make a Fail-Safe System: ......................................................................................................................... 5 Getting Started: ..................................................................................................................................................... 6 Components: ............................................................................................................................................. 6 Features of the Single Input High or Low Alarm Relay: ............................................................................ 7 Features of the Dual Input Automation Fill/Empty Relay: ......................................................................... 8 Guide to Controls: ..................................................................................................................................... 9 Wiring: ................................................................................................................................................................ 10 Connecting Switches to Input Terminals: ................................................................................................ 10 LED Indication: ........................................................................................................................................ 10 Relay and Power Terminals: ................................................................................................................... 11 VAC Power Input Wiring: ........................................................................................................................ 11 Changing from 120 to 240 VAC .............................................................................................................. 11 Installation: .......................................................................................................................................................... 12 Panel DIN Rail Mounting: ........................................................................................................................ 12 Application Exmaples ......................................................................................................................................... 13 Low Level Alarm: .................................................................................................................................... 13 High Level Alarm: .................................................................................................................................... 13 Pump Protection: .................................................................................................................................... 14 Automatic Fill: ......................................................................................................................................... 14 Automatic Empty: .................................................................................................................................... 15 Leak Detection: ....................................................................................................................................... 15 Appendix: ............................................................................................................................................................ 16 Relay Logic: Automatic Filling and Emptying: ......................................................................................... 16 Latch – On vs. Off: .................................................................................................................................. 17 Controller Logic: ...................................................................................................................................... 17 Troubleshooting: ..................................................................................................................................... 18 Testing Relays: ....................................................................................................................................... 18 Warranty: ............................................................................................................................................................ 20

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Specifications / Dimensions Step Two

SPECIFICATIONS: Supply voltage: 120 / 240 VAC, 50 - 60 Hz.

Consumption: 5 Watts max.

Sensor inputs: (1) level switch

(LC41 Series only) (1 or 2) level switches

(LC42 Series only) (1, 2 or 3) level switches

Sensor supply: 13.5 VDC @ 27 mA per input

LED indication: Sensor, relay & power status

Contact type: (1) SPDT Relay

(LC41 Series only) (1) SPDT Relay, Latched

(LC42 Series only) (2) SPDT Relays, only 1 Latched

Contact rating: 250 VAC, 10A

Contact output: Selectable NO or NC

Contact latch: Select On/Off – LC41 & LC42 only

Contact delay: 0.15 to 60 seconds

Electronics temp.: F: -40°to 158°

C: -40°to 70°

Enclosure type: 35mm DIN (EN 50 022)

Enclosure material: PP (U.L. 94 VO)

Fail safety: Power fail-safe

Certificate number: LR 79326

DIMENSIONS: Top View - All Models

Side View - All Models

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Specifications / Dimensions Step Two

CONTROLLER LABELS: LC40 series faceplate: 1 sensor input, 1 relay output.

LC41 series faceplate: 2 sensor inputs, 1 relay output. The relay included is a latching relay.

LC42 series faceplate: 3 sensor input, 2 relay outputs. One relay is latching and the other is a single input relay.

INTERNAL CONTROLLER LOGIC:

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Safety Precautions Step Three

About This Manual: PLEASE READ THE ENTIRE MANUAL PRIOR TO INSTALLING OR USING THIS PRODUCT. This manual includes information on three different models of Remote Relay Controllers from FLOWLINE: LC40, LC41 and LC42 series. Many aspects of installation and use are similar between the three models. Where they differ, the manual will note it. Please refer to the part number on the controller you have purchased as you read.

User’s Responsibility for Safety: FLOWLINE manufactures several models of controller, with different mounting and switching configurations. It is the user’s responsibility to select a controller model that is appropriate for the application, install it properly, perform tests of the installed system, and maintain all components.

Electrical Shock Hazard: It is possible to contact components on the controller that carry high voltage, causing serious injury or death. All power to the controller and the relay circuit(s) it controls should be turned OFF prior to working on the controller. If it is necessary to make adjustments during powered operation, use extreme caution and use only insulated tools. Making adjustments to powered controllers is not recommended. Wiring should be performed by qualified personnel in accordance with all applicable national, state and local electrical codes.

Flammable or Explosive Applications: The entire LC40 series remote mount controllers should not be used with explosive or flammable liquids, which require an intrinsically safe or explosion proof rating such as the FLOWLINE LC90 series. If you are unsure of the suitability of a controller for your installation, consult your Flowline representative for further information.

Install In a Dry Location: The controller housing is not designed to be immersed. When installed properly, it should be mounted in such a way that it does not normally come into contact with liquid. Refer to an industry reference to ensure that compounds that may splash onto the controller housing will not damage it. Such damage is not covered by the warranty.

Relay Contact Rating: The relay is rated for a 10 amp resistive load. Many loads (such as a motor during start-up or incandescent lights) are reactive and may have an inrush current characteristic that may be 10 to 20 times their steady-state load rating. The use of a contact protection circuit may be necessary for your installation if the 10 amp rating does not provide an ample margin for such inrush currents.

Make a Fail-Safe System: Design a fail-safe system that accommodates the possibility of relay or power failure. If power is cut off to the controller, it will de-energize the relay. Make sure that the de-energized state of the relay is the safe state in your process. For example, if controller power is lost, a pump filling a tank will turn off if it is connected to the Normally Open side of the relay.

While the internal relay is reliable, over the course of time relay failure is possible in two modes: under a heavy load the contacts may be “welded” or stuck into the energized position, or corrosion may buildup on a contact so that it will not complete the circuit when it should. In critical applications, redundant backup systems and alarms must be used in addition to the primary system. Such backup systems should use different sensor technologies where possible.

While this manual offers some examples and suggestions to help explain the operation of FLOWLINE products, such examples are for information only and are not intended as a complete guide to installing any specific system.

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Getting Started Step Four

COMPONENTS:

Part Number Power Inputs Alarm Relay

Latching Relay

Function

LC40-1001 120 VAC

1 1 0 High Level, Low Level or Pump Protection

LC40-1001-E 240 VAC

LC41-1001 120 VAC

2 0 1 Automatic Fill, Automatic Empty, High Level, Low Level or Pump Protection.

LC41-1001-E 240 VAC

LC42-1001 120 VAC

3 1 1

Alarm (Relay 1) - High Level, Low Level or Pump Protection

Latching (Relay 2) - Automatic Fill, Automatic Empty, High Level, Low Level or Pump Protection.

LC42-1001-E 240 VAC

Owner’s Manual 240 VAC OPTION: When ordering any 240 VAC version of the LC40 series, the controller will arrive configured for 240 VAC operation. 240 VAC versions will include a –E to the part number (i.e. LC40-1001-E).

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Getting Started Step Four

FEATURES OF A SINGLE INPUT HIGH OR LOW RELAY: Single Input Relays (LC40 series, LC41 series with latch turned OFF and LC42 series) are designed to receive a signal from a single liquid sensor. It turns its internal relay ON or OFF (as set by the invert switch) in response to the presence of liquid, and changes the relay status back again when the sensor is dry.

High Alarm: Invert is OFF. Relay will energize when the switch becomes Wet and will de-energize when the switch becomes Dry (out of liquid).

Low Alarm: Invert is ON. Relay will energize when the switch becomes Dry (out of liquid) and will de-energize when the switch becomes Wet.

Single Input Relays may be used with almost any kind of sensor signal: current sensing or contact closure. The relay is a single pole, double throw type; the controlled device can be connected to either the normally open or normally closed side of the relay. A time delay from 0 to 60 seconds can be set before the relay responds to the sensor input. Typical applications for Single Input Relays are high level or low level switch/alarm operations (opening a drain valve whenever liquid level rises to a sensor point) and leak detection (sounding an alarm when a leak is detected, etc.).

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Getting Started Step Four

FEATURES OF A DUAL INPUT AUTOMATIC FILL/EMPTY RELAY: The Dual Input Automatic Fill/Empty Relay (LC41 and LC42 series only) is designed to receive signals from two liquid sensors. It turns its internal relay ON or OFF (as set by the invert switch) in response to the presence of liquid on both sensors, and changes the relay status back again when both sensors are dry.

Automatic Empty: Latch is ON & Invert is OFF. Relay will energize when level reaches high switch (both switches are wet). Relay will de-energize when level is below the bottom switch (both switches are dry).

Automatic Fill: Latch is ON & Invert is ON. Relay will energize when level is below the bottom switch (both switches are dry). Relay will de-energize when level reaches high switch (both switches are wet).

The Dual Input Automatic Fill/Empty Relay may be used with almost any kind of sensor signal: current sensing or contact closure. The relay is a single pole, double throw type; the controlled device can be connected to either the normally open or normally closed side of the relay. A time delay from 0 to 60 seconds can be set before the relay responds to the sensor input. Typical applications for Dual Input Relays are automatic filling (starting fill pump at a low level and stopping pump at a high level) or automatic emptying operations (opening a drain valve at a high level and closing valve at low level).

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Getting Started Step Four

GUIDE TO CONTROLS: Below is a listing and the location of the different components for the controller:

1. Power indicator: This green LED lights when AC power is ON.

2. Relay indicator: This red LED will light whenever the controller energizes the relay, in response to the proper condition at the sensor input(s) and after the time delay.

3. AC Power terminals: Connection of 120 VAC power to the controller. The setting may be changed to 240 VAC if desired. This requires changing internal jumpers; this is covered in the Installation section of the manual. Polarity (neutral and hot) does not matter.

4. Relay terminals (NC, C, NO): Connect the device you wish to control (pump, alarm etc.) to these terminals: supply to the COM terminal, and the device to the NO or NC terminal as required. The switched device should be a non-inductive load of not more than 10 amps; for reactive loads the current must be derated or protection circuits used. When the red LED is ON and the relay is in the energized state, the NO terminal will be closed and the NC terminal will be open.

5. Time delay: Use potentiometer to set delay from 0.15 to 60 seconds. Delay occurs during switch make and switch break.

6. Input indicators: Use these LEDs for indicating WET or DRY status of switch. When switch is WET, LED will be Amber. When switch is DRY, LED will either be Green for powered switches or OFF for reed switches. Note: Reed switches may be reversed for WET/OFF, DRY/Amber LED indication.

7. Invert switch: This switch reverses the logic of the relay control in response to the switch(es): conditions that used to energize the relay will now de-energize the relay and vice versa.

8. Latch switch (LC41 and LC42 series only): This switch determines how the relay will be energized in response to the two sensor inputs. When LATCH is OFF, the relay responds to sensor Input A only; when LATCH is ON, the relay will energize or de-energize only when both switches (A and B) are in the same condition (both wet or both dry). The relay will remain latched until both switches change conditions.

9. Input terminals: Connect the switch wires to these terminals: Note the polarity: (+) is a 13.5 VDC, 30 mA power supply (connected to the red wire of a FLOWLINE powered level switch), and (-) is the return path from the sensor (connected to the black wire of a FLOWLINE powered level switch). With powered level switches, if the wires are reversed, the sensor will not work. With reed switches, wire polarity does not matter.

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Wiring Step Five

CONNECTING SWITCHES TO INPUT TERMINALS: Please note a difference between FLOWLINE powered level switches and mechanical reed switches. All powered level switches (series LZ12, LU10, LP15, LP50 & LO10 series) will be wired with the Red wire to the (+) terminal and the Black wire to the (-) terminal. FLOWLINE mechanical reed switches (series LV10, LV2_, LV3_, LV4_, LH2_ & LH3_ series) will have a particular wiring based upon part number. See the illustration below to indicate wiring for your switch.

Note: the Shield wire will be used only for long cable runs or where excessive electrical noise is present.

* LV10 series can be wired using the White and Black wires for NO operations or the Red and Black wires for NC operations.

LED INDICATION: Use LED's located above the input terminals to indicate whether the switch is in a wet or dry state.

Powered level switches: o Green indicates dry o Amber indicates wet

Mechanical reed switches: o Amber indicates wet o No LED indicates dry.

Note: Mechanical reed switches may be wired in reverse so that Amber indicates a dry state and no LED indicates a wet state.

Powered Level Switches

Mechanical Reed Switches

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Wiring Step Five

RELAY AND POWER TERMINALS Depending on the model selected, there will be either one or two relays. The label for the relay applies for both relays. Each terminal has a Normally Open (NC), Common (C) and Normally Open (NO) terminal. The relay(s) is(are) a single pole, double throw (SPDT) type rated at 250 Volts AC, 10 Amps, 1/4 Hp.

Note: The relay contacts are true dry contacts. There is no voltage sourced within the relay contacts.

Note: The "normal" state is when the relay coil is de-energized and the Red relay LED is Off / de-energized.

VAC POWER INPUT WIRING: The Power Terminal is located next to the Relay(s). Observe the Power Supply label, which identifies the power requirement (120 or 240 VAC) and the terminal wiring.

Note: Polarity does not matter with the AC input terminal.

CHANGING FROM 120 TO 240 VAC: 1. Remove the back panel of the controller and

gently slide the printed circuit board from the housing. Use caution when removing the PCB.

2. Located jumpers JWA, JWB and JWC on the PCB.

3. To change to 240 VAC, remove jumpers from JWB and JWC and place a single jumper across JWA. To change to 120 VAC, remove jumper JWA and place jumpers across JWB and JWC.

4. Gently return PCB into housing and replace back panel.

120 VAC 240 VAC Configuration Configuration

240 VAC OPTION: When ordering any 240 VAC version of the LC40 series, the sensor will arrive configured for 240 VAC operation. 240 VAC versions will include a –E to the part number (i.e. LC40-1001-E).

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Installation Step Six

PANEL DIN RAIL MOUNTING: The controller may be mounted by either a back panel using two screws through mounting holes located at the corners of the controller or by snapping the controller on 35 mm DIN Rail.

Note: Always install the controller in a location where it does not come into contact with liquid.

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Application Examples Step Seven

LOW LEVEL ALARM: The goal is to make sure that an operator is notified if the liquid level falls below a certain point. If it does, an alarm will sound, alerting the operator of a low level. A level switch must be mounted at the location where the alarm will sound.

In this application, the level switch will be Wet all the time. When the level switch becomes Dry, the relay contact will close causing the alarm to activate. Normal status for the application is for the controller to hold the relay open with the alarm wired through the Normally Closed contact. The Relay will be energized, the relay LED will be On and Invert will be Off. When the level switch becomes Dry, the relay will de-energize causing the contact to close allowing the alarm to activate.

To do this, connect the hot lead of the alarm to the NC side of the relay terminal of the controller. If power is lost, the relay will be de-energized, and the alarm will sound (if there is still power to the alarm circuit itself).

Note: If power is accidentally cut to the controller, the level switch’s ability to notify the operator of a low level alarm could be lost. To prevent this, the alarm circuit should have a non-interruptible power supply or some other independent power source. HIGH LEVEL ALARM: In the same manor, this system can be used to sound an alarm when fluid reaches a high level, with just a change in the location of the sensor and the setting of the Invert switch.

The alarm is still connected to the NC side of the relay to allow for a power failure alarm.

The sensor is normally dry. In this condition, we want the relay to be energized so the alarm does not sound: i.e., the Red relay LED should be on whenever the Input LED is Amber. So we turn Invert On. If the fluid level rises to the high sensor point, the sensor goes on, the relay de-energizes, and the alarm sounds.

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Application Examples Step Seven

PUMP PROTECTION: The key here is to install a level switch just above the outlet to the pump. As long as the switch is Wet, the pump can operate. If the switch ever becomes Dry, the relay will open preventing the pump from running. To prevent relay chatter, add a small relay delay.

Note: In this application, the relay to the pump must be closed while the level switch is Wet. To do this, connect the relay through the NO side of the relay and set Invert to the OFF position. If power is lost to the controller, the relay will de-energize and keep the circuit open preventing the pump from running.

AUTOMATIC FILL: This system consists of a tank with a high level sensor, a low level sensor, and a valve that is controlled by the controller. Part of a proper fail-safe design for this particular system is that if power is lost to the controller for any reason, the valve filling the tank must be closed. Therefore, we connect the valve to the NO side of the relay. When the relay is energized, the valve will open and fill the tank. In this case, Invert should be ON. The relay indicator will correspond directly to the open/close status of the valve.

Determining the settings of LATCH and INVERT: This is the way the system must operate:

When both the high and low sensors are dry, the valve will open (relay energized), starting to fill the tank.

When the low sensor gets wet, the valve will remain open (relay energized).

When the high sensor gets wet, the valve will close (relay de-energized.

When the high sensor becomes dry, the valve will remain closed (relay de-energized).

Latch: In any two-sensor control system, LATCH must be ON.

Invert: Referring to the logic chart in Step Eight, we look for the setting that will de-energize the relay (start the pump) when both inputs are wet (Amber LEDs). In this system, Invert should be ON.

Determining A or B input connections: When LATCH is ON, there is no effective difference between Input A and B, since both sensors must have the same signal in order for status to change. When wiring any two-input relay section, the only consideration for hooking a particular sensor to A or B is if LATCH will be OFF.

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Application Examples Step Seven

AUTOMATIC EMPTY: Similar system logic can be used for an automatic empty operation. In this example, we will use a pump to empty a tank. The system still consists of a tank with a high level sensor, a low level sensor, and a pump that is controlled by the controller.

Note: Fail-safe design is critical in an application where the tank is passively filled. A power failure to the controller or the pump circuits may cause the tank to overflow. A redundant high alarm is critical to prevent an overflow.

Connect the pump to the NO side of the relay. In this case, Invert should be OFF, when the relay is energized, the pump will run and empty the tank. The relay indicator will correspond directly to the on/off status of the pump.

Note: If the pump motor load exceeds the rating of the controller’s relay, a stepper relay of higher capacity must be used as part of the system design.

LEAK DETECTION:

A leak detection switch is installed either inside the interstitial space of the tank or through the outer wall. The switch will remain wet 99.99% of the time. Only when liquid comes into contact with the switch will the relay close to activate an alarm.

The alarm is connected to the NC side of the relay to allow for a power failure alarm.

Note: The sensor is normally dry. In this condition, we want the relay to be energized so the alarm does not sound: i.e., the Red relay LED should be on whenever the Input LED is Amber. So we turn Invert On. If liquid comes into contact with the switch, the switch activates, the relay de-energizes, and the alarm sounds.

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Appendix Step Eight

RELAY LOGIC – AUTOMATIC FILLING AND EMPTYING Latching relay will only switch when both level switches are in the same state.

One Switch Dry, One Wet Both Switches Wet Both Switches Dry

In this state, the relay will never switch, regardless if this is an Auto Fill or Auto Empty application.

In this state, the relay will typically energize for an Auto Empty application and will typically de-energize for an Auto Fill application.

In this state, the relay will typically energize for an Auto Fill application and will typically de-energize for an Auto Empty application.

Note: The state of the application (either filling or emptying) can never be confirmed when one switch is Wet and the other is Dry. Only when both switches are in the same state (both Wet or both Dry) can confirmation of the relay status (energized or de-energized) occur. Note: Always check the status of the level switches and compare that status against the Input LEDs. If the level switches state (Wet or Dry) corresponds to the Input LEDs, proceed to the relay. If the level switches state (Wet or Dry) does not correspond to the input LEDs, then check the functionality of the level switches. RELAY LOGIC – INDIEPENDENT RELAY Relay will act directly based upon the status of the level switch. When the level switch is Wet, the input LED will be ON (Amber). When the level switch is Dry, the input LED will be Off.

Single Switch Wet Single Switch Dry

In this state, the relay can be energized with Invert in the OFF setting or can be de-energized with Invert in the ON setting.

In this state, the relay can be energized with Invert in the ON setting or can be de-energized with Invert in the OFF setting.

Note: Always check the status of the level switch and compare that status against the Input LED. If the level switch state (Wet or Dry) corresponds to the Input LED, proceed to the relay. If the level switch state (Wet or Dry) does not correspond to the input LED, then check the functionality of the level switch.

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Appendix Step Eight

LATCH - ON VS OFF: The relay can either be an independent relay (high level, low level or pump protection) with Latch OFF or can be a latching relay (automatic fill or empty) with Latch ON.

With Latch OFF, the relay will only respond to INPUT A. INPUT B will be ignored while Latch is OFF.

Invert OFF Latch OFF

Input A* Input B* Relay ON No Effect ON OFF No Effect OFF

Invert ON Latch OFF

Input A* Input B* Relay ON No Effect OFF OFF No Effect ON

With Latch ON, the relay will actuate when INPUT A and INPUT B are in the same condition. The relay will not change its condition until both inputs reverse their state.

Invert OFF Latch ON

Input A* Input B* Relay ON ON ON

OFF ON No

Change

ON OFF No

Change OFF OFF ON

Invert ON Latch ON

Input A* Input B* Relay ON ON OFF

OFF ON No

Change

ON OFF No

Change OFF OFF ON

Note: Some sensors (particularly buoyancy sensors) may have their own inverting capability (wired NO or NC). This will change the logic of the invert switch. Check your system design. CONTROLLER LOGIC: Please use the following guide to understand the operation of the controllers.

1. Power LED: Make sure the Green power LED is ON when power is supplied to the controller.

2. Input LED(s): The input LED(s) on the controller will be Amber when the switch(es) is/are wet and Green or OFF when the switch(es) is/are dry. If the LED's are not switching the input LED, test the level switch.

3. Alarm Relay (1 input): When the input LED turn OFF and ON, the relay LED will also switch. With invert OFF, the relay LED will be ON when the input LED is ON and OFF when the input LED is OFF. With invert ON, the relay LED will be OFF when the input LED is ON and ON when the input LED is OFF.

4. Latching Relay (2 inputs): When both inputs are wet (Amber LED's ON), the relay will be energized (Red LED ON). After that, if one switch becomes dry, the relay will remain energized. Only when both switches are dry (both amber LED's OFF) will the controller de-energize the relay. The relay will not energize again until both switches are wet. See the Relay Latch Logic Chart below for further explanation.

TIME DELAY: The time delay can be adjusted from 0.15 seconds to 60 seconds. The delay applies to both the Make and Break side of the relay. The delay can be used to prevent relay chatter, especially when you have a liquid level that is turbulent. Typically, a slight rotation clockwise, from a position of all the way counter-clockwise, is enough to prevent relay chatter.

Note: The delay has stops on each end of its 270° rotation.

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Appendix Step Eight

TROUBLESHOOTING:

PROBLEM SOLUTION Relay switches only from input A (ignores input B)

Latch is turned OFF. Flip the latch switch to turn ON.

Level reaches alarm ON, but relay is OFF.

First, check to make sure the input LED is ON. If not, check wiring to sensor. Second, check status of Relay LED. If incorrect, flip the Invert switch to change the relay state.

Pump or Valve is supposed to stop, but it does not.

First, check to make sure the input LEDs are both in the sate state (both ON or both OFF). If not, check wiring to sensor each sensor. Second, check status of Relay LED. If incorrect, flip the Invert switch to change the relay state.

Controller is powered, but nothing happens.

First check the Power LED to make sure it is Green. If not, check the wiring, power and make sure the terminal is seated correctly over the 6-pins.

TESTING RELAYS: Normally Open (NO) Wiring:

The relay contacts are true dry contacts with no voltage sourced within the relay contacts. To test, connect a Multimeter set to read Ohms.

Normally Open Wiring With Invert Off, circuit will be

Open. With Invert ON, circuit will

read a small resistance.

Normally Closed Wiring With Invert Off, circuit will be

read a small resistance. With Invert ON, circuit will be

open.

Normally Closed (NC) Wiring:

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Left

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Warranty, Returns and Limitations Step Nine

WARRANTY Flowline warrants to the original purchaser of its products that such products will be free from defects in material and workmanship under normal use and service in accordance with instructions furnished by Flowline for a period of two years from the date of manufacture of such products. Flowline's obligation under this warranty is solely and exclusively limited to the repair or replacement, at Flowline's option, of the products or components, which Flowline's examination determines to its satisfaction to be defective in material or workmanship within the warranty period. Flowline must be notified pursuant to the instructions below of any claim under this warranty within thirty (30) days of any claimed lack of conformity of the product. Any product repaired under this warranty will be warranted only for the remainder of the original warranty period. Any product provided as a replacement under this warranty will be warranted for the full two years from the date of manufacture.

RETURNS Products cannot be returned to Flowline without Flowline's prior authorization. To return a product that is thought to be defective, go to www.flowline.com, and submit a customer return (MRA) request form and follow the instructions therein. All warranty and non-warranty product returns to Flowline must be shipped prepaid and insured. Flowline will not be responsible for any products lost or damaged in shipment.

LIMITATIONS This warranty does not apply to products which: 1) are beyond the warranty period or are products for which the original purchaser does not follow the warranty procedures outlined above; 2) have been subjected to electrical, mechanical or chemical damage due to improper, accidental or negligent use; 3) have been modified or altered; 4) anyone other than service personnel authorized by Flowline have attempted to repair; 5) have been involved in accidents or natural disasters; or 6) are damaged during return shipment to Flowline. Flowline reserves the right to unilaterally waive this warranty and dispose of any product returned to Flowline where: 1) there is evidence of a potentially hazardous material present with the product; or 2) the product has remained unclaimed at Flowline for more than 30 days after Flowline has dutifully requested disposition. This warranty contains the sole express warranty made by Flowline in connection with its products. ALL IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, THE WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE, ARE EXPRESSLY DISCLAIMED. The remedies of repair or replacement as stated above are the exclusive remedies for the breach of this warranty. IN NO EVENT SHALL FLOWLINE BE LIABLE FOR ANY INCIDENTAL OR CONSEQUENTIAL DAMAGES OF ANY KIND INCLUDING PERSONAL OR REAL PROPERTY OR FOR INJURY TO ANY PERSON. THIS WARRANTY CONSTITUTES THE FINAL, COMPLETE AND EXCLUSIVE STATEMENT OF WARRANTY TERMS AND NO PERSON IS AUTHORIZED TO MAKE ANY OTHER WARRANTIES OR REPRESENTATIONS ON BEHALF OF FLOWLINE. This warranty will be interpreted pursuant to the laws of the State of California. If any portion of this warranty is held to be invalid or unenforceable for any reason, such finding will not invalidate any other provision of this warranty.

For complete product documentation, video training, and technical support, go to www.flowline.com. For phone support, call 562-598-3015 from 8am to 5pm PST, Mon - Fri. (Please make sure you have the Part and Serial number available.)